Tom Ellaby scite author profile

Platinum nanoparticles find significant use as catalysts in industrial applications such as fuel cells. Research into their design has focussed heavily on nanoparticle size and shape as they greatly influence activity. Using high throughput, high precision electron microscopy, the structures of commercially available Pt catalysts have been determined, and we have used classical and quantum atomistic simulations to examine and compare them with geometric cuboctahedral and truncated octahedral structures. A simulated annealing procedure was used both to explore the potential energy surface at different temperatures, and also to assess the effect on catalytic activity that annealing would have on nanoparticles with different geometries and sizes. The differences in response to annealing between the real and geometric nanoparticles are discussed in terms of thermal stability, coordination number and the proportion of optimal binding sites on the surface of the nanoparticles. We find that annealing both experimental and geometric nanoparticles results in structures that appear similar in shape and predicted activity, using oxygen adsorption as a measure. Annealing is predicted to increase the catalytic activity in all cases except the truncated octahedra, where it has the opposite effect. As our simulations have been performed with a classical force field, we also assess its suitability to describe the potential energy of such nanoparticles by comparing with large scale density functional theory calculations.

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Melting of large Pt@MgO(1 0 0) icosahedra

Rossi

Ellaby

Paz-Borbón

et al. 2017

J. Phys.: Condens. Matter

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On the basis of ab initio calculations, we present a new parametrisation of the Vervisch-Mottet-Goniakowski (VMG) potential (Vervisch et al 2002 Phys. Rev. B 24 245411) for modelling the oxide-metal interaction. Applying this model to mimic the finite temperature behaviour of large platinum icosahedra deposited on the pristine MgO(1 0 0), we find the nanoparticle undergoes two solid-solid transitions. At 650 K the 'squarisation' of the interface layer, while a full reshaping towards a fcc architecture takes place above 950 K. In between, a quite long-lived intermediate state with a (1 0 0) interface but with an icosahedral cap is observed. Our approach reproduces experimental observations, including wetting behaviour and the lack of surface diffusion.

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Strain effects in core–shell PtCo nanoparticles: a comparison of experimental observations and computational modelling

Ellaby

Varambhia

Luo

et al. 2020

Phys. Chem. Chem. Phys.

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Modification of O and CO binding on Pt nanoparticles due to electronic and structural effects of titania supports

Ellaby

Briquet

Sarwar

et al. 2019

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Metal oxide supports often play an active part in heterogeneous catalysis by moderating both the structure and the electronic properties of the metallic catalyst particle. In order to provide some fundamental understanding on these effects, we present here a DFT investigation of the binding of O and CO on Pt nanoparticles supported on titania (anatase) surfaces. These systems are complex and in order to develop realistic models here we needed to perform DFT calculations with up to ∼1000 atoms. By performing full geometry relaxations at each stage, we avoid any effects of "frozen geometry" approximations. In terms of the interaction of the Pt nanoparticles with the support, we find that the surface deformation of the anatase support contributes greatly to the adsorption of each nanoparticle, especially for the anatase (001) facet. We attempt to separate geometric and electronic effects, and find a larger contribution to ligand binding energy arising from the former. Overall, we show an average weakening (compared to the isolated nanoparticle) of ∼0.1 eV across atop, bridge and hollow binding sites on supported Pt 55 for O and CO, and a preservation of site preference. Stronger effects are seen for O on Pt 13 , which is heavily deformed by anatase supports. In order to rationalise our results and examine methods for faster characterisation of metal catalysts, we make use of electronic descriptors, including the d-band centre and our electronic density based descriptor. We expect that the approach followed in this study could be applied to study other supported metal catalysts.

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Quantum computation for periodic solids in second quantization

Ivanov

Sünderhauf

Holzmann

et al. 2023

Phys. Rev. Research

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Tom Ellaby

Ideal versus real: simulated annealing of experimentally derived and geometric platinum nanoparticles

Melting of large Pt@MgO(1 0 0) icosahedra

Strain effects in core–shell PtCo nanoparticles: a comparison of experimental observations and computational modelling

Modification of O and CO binding on Pt nanoparticles due to electronic and structural effects of titania supports

Quantum computation for periodic solids in second quantization

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